[1] YAN H, WANG X, YU B, et al. Adaptive integrated guidance and control based on backstepping and input-to-state stability[J].Asian Journal of Control, 2014, 16(2):602-608. [2] HE S M, WANG W, LIN D F. Adaptive backstepping impact angle guidance law accounting for autopilot Lag[J].Journal of Aerospace Engineering, 2017, 30(3):04016094. [3] MAN C Y, ZHANG Z X, LI S H. Two composite guidance laws based on the backstepping control and disturbance observers with autopilot lag[J]. Transa-ctions of the Institute of Measurement and Control,2019,41(10):2957-2969. [4] 司玉洁, 熊华, 宋勋, 等. 三维自适应终端滑模协同制导律[J].航空学报,2020,41(51):723759 SI Y J, XIONG H, SONG X, et al. Three dimensional adaptive terminal sliding mode cooperative guidance law[J].Acta Aeronautica et Astronautica Sinica,2020,41(51):723759(in Chinese). [5] LYU T, LI C H, GUO Y N, et al. Three-dimensional finite-time cooperative guidance for multiple missiles without radial velocity measurements[J]. Chinese Journal of Aeronautics,2019,32(5):1294-1304. [6] SI Y J, SONG S M. Three-dimensional adaptive finite-time guidance law for intercepting maneuvering targets[J]. Chinese Journal of Aeronautics,2017,30(6):1985-2003. [7] 严晗, 季海波. 弹道坐标中三维鲁棒非线性导引律[J]. 控制理论与应用,2013,30(9):1079-1085. YAN H, JI H B, Three-dimensional robust nonlinear guidance law in trajectory coordinates[J]. Control Theory & Applications, 2013,30(9):1079-1085(in Chinese). [8] SONG B, HEDRICK J K. Simultaneous quadratic stabilization for a class of non-linear systems with input saturation using dynamic surface control[J]. International Journal of Control, 2004,77(1):19-26. [9] ZHOU D, XU B. Adaptive dynamic surface guidance law with input saturation constraint and autopilot dynamics[J]. Journal of Guidance, Control, and Dynamics, 2016, 39(5):1152-1159. [10] RASHAD R, ABOUDONIA A, EL-BADAWY A. A novel disturbance observer-based backstepping controller with command filtered compensation for a MIMO system[J]. Journal of the Franklin institute,2016,353(16):4039-4061. [11] DONG W J, FARRELL J A, POLYCARPOU M M, et al. Command filtered adaptive backstepping[J]. IEEE Transactions on Control Systems Technology, 2012, 20(3):566-80. [12] WANG L, ZHANG W H, WANG D H, et al. Command filtered back-stepping missile integrated guidance and autopilot based on extended state observer[J]. Advances in Mechanical Engineering,2017,9(11):1-13. [13] 董朝阳,路遥,王青.高超声速飞行器指令滤波反演控制[J].宇航学报,2016,37(8):957-963. DONG C Y, LU Y, WANG Q. Command filtered backstepping control for hypersonic vehicle[J].Journal of Astronautics, 2016,37(8):957-963(in Chinese). [14] 毛柏源, 李君龙, 张锐. 考虑自动驾驶仪动态特性的多约束中制导律[J]. 系统工程与电子技术, 2019,41(2):382-388. MAO B Y, LI J L, ZHANG R. Midcourse guidance law with multiple constraints considering missile's dynamics of autopilot[J]. Journal of Systems Engineering and Electronics, 2019,41(2):382-388(in Chinese). [15] 张宽桥,杨锁昌,李宝晨,等.考虑驾驶仪动态特性的固定时间收敛制导律[J].航空学报, 2019,40(11):323227. ZHANG K Q, YANG S C, LI B C, et al. Fixed-time convergent guidance law considering autopilot d-ynamics[J].Acta Aeronautica et Astronautica Sinica, 2019,40(11):323227(in Chinese). [16] 赵国荣,李晓宝,刘帅,等.考虑自动驾驶仪延迟的多约束末制导律[J].兵器装备工程学报,2019,40(10):1-6. ZHAO G R, LI X B, LIU S, et al. Guidance law with drop angle and field-of-view angle constraints considering autopilot lag[J].Journal of Ordnance Equipment Engineering, 2019,40(10):1-6(in Chinese). [17] CHWA D. Global tracking control of underactuated ships with input and velocity constraints using dynamic surface control method[J]. IEEE Transactions on Control systems technology, 2011, 19(6):1357-1370. [18] 骆长鑫,张东洋,雷虎民,等.输入受限的高超声速飞行器鲁棒反演控制[J].航空学报,2018,39(4):321801. LUO C X, ZHANG D Y, LEI H M, et al. Robust backstepping control of input-constrained hypersonic vehicle[J]. Acta Aeronautica et Astronautica Sinica, 2018,39(4):321801(in Chinese). [19] 王松艳,孙向宇,杨胜江,等.考虑输入饱和的制导控制一体化设计[J].航空学报,2017,38(10):320897. WANG S Y, SUN X Y, YANG S J, et al. Integrat-ed guidance and control design considering input saturation[J].Acta Aeronautica et Astronautica Sinica, 2017,38(10):320897(in Chinese). [20] 孟克子,周荻.过载指令约束下的导弹导引律设计[J].兵工学报,2014,35(9):1419-1427. MENG K Z, ZHOU D. Design of missile guidance law subject to acceleration command constraint[J]. Acta Armamentarii, 2014,35(9):1419-1427(in Chinese). [21] DU R L, MENG K Z, ZHOU D, et al. Design of three-dimensional nonlinear guidance law with bounded acceleration command[J]. Aerospace Science and Technology,2015,46:168-175. [22] DUAN M J, ZHOU D, CHENG D L. Extended state observer-based finite-time guidance laws on account of thruster dynamics[J]. Proceedings of the Institution of Mechanical Engineers, Part G:Journal of Aerospace Engineering,2019,233(12):4583-4597. [23] 陈泽宏,钟继鸿,赵宏宇,等.基于扩张状态观测器的有限时间收敛制导律[J].空天防御, 2019,2(3):25-30. CHEN Z H, ZHONG J H, ZHAO H Y, et al. Fini-te time convergent guidance law based on exten-ded state observer[J]. Air & Space Defense, 2019,2(3):25-30(in Chinese). [24] 张文杰,鲁天宇,夏群利.基于扩张状态观测器的反预警滑模制导律[J].系统工程与电子技术,2019,41(5):1087-1093. ZHANG W J, LU T Y, XIA Q L. Anti-early-warning airplane sliding mode guidance law based on extended state observer[J]. Journal of Systems Engineering and Electronics, 2019,41(5):1087-1093(in Chinese). [25] ZHOU D, SUN S, TEO K L. Guidance laws with finite time convergence[J]. Journal of Guidance, Control, and Dynamics, 2009, 32(6):1838-1846. [26] 韩京清.自抗扰控制技术-估计补偿不确定因素的控制技术[M].北京:国防工业出版社,2008:221-237 HAN J Q. Active disturbance rejection control technique:the technique for estimating and compensating the uncertainties[M]. Beijing:National Defence Industry Press,2008:221-237. |